Abstract
Methylthioadenosine, the main by-product of spermidine synthesis, is degraded in Bacillus subtilis as adenine and methylthioribose. The latter is an excellent sulfur source and the precursor of quorum-sensing signalling molecules. Nothing was known about methylthioribose recycling in this organism. Using trifluoromethylthioribose as a toxic analog to select for resistant mutants, we demonstrate that methylthioribose is first phosphorylated by MtnK, methylthioribose kinase, the product of gene mtnK (formerly ykrT), expressed as an operon with mtnS (formerly ykrS) in an abundant transcript with a S-box leader sequence. Although participating in methylthioribose recycling, the function of mtnS remained elusive. We also show that MtnK synthesis is boosted under starvation condition, in the following decreasing order: carbon-, sulfur- and nitrogen-starvation. We finally show that this enzyme is part of the family Pfam 01633 (choline kinases) which belongs to a large cluster of orthologs comprizing antibiotic aminoglycoside kinases and protein serine/threonine kinases. The first step of methylthioribose recycling is phosphorylation by MTR kinase, coded by the mtnK (formerly ykrT) gene. Analysis of the neighbourhood of mtnK demonstrates that genes located in its immediate vicinity (now named mtnUVWXYZ, formerly ykrUVWXYZ) are also required for methylthioribose recycling.
Highlights
Methylthioadenosine, the main by-product of spermidine synthesis, is degraded in Bacillus subtilis as adenine and methylthioribose
In the course of our study of sulfur metabolism in bacteria we have witnessed that expression of many genes was induced when cells were deprived of sulfur [1]
We used an analogue of MTR, trifluoromethylthioribose (3F-MTR), which has been assayed as a possible drug lead for killing pathogens [10]
Summary
Methylthioadenosine, the main by-product of spermidine synthesis, is degraded in Bacillus subtilis as adenine and methylthioribose. The latter is an excellent sulfur source and the precursor of quorum-sensing signalling molecules. Aminopropyl transfer, during polyamine metabolism, yields methylthioadenosine, which is split into adenine and methylthioribose by the mtnA gene (yrrU) [3]. This molecule is excreted in Escherichia coli[4], and degraded by oxidation steps in Klebsiella pneumoniae[5]. Further study of the gene uncovered an unusual expression pattern under starvation conditions, discussed in the present article
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